Articulated bending support

ABSTRACT

A process for gravity bending of a glass sheet on a support including a chassis, a first frame and a second frame, the second frame being articulated and including a mobile lateral part that passes from an open position to a closed position by an articulation during the bending procedure, the bending of the sheet beginning on the first frame while the second frame is in the open position, and finishing on the second frame in the closed position, the sheet passing from the first frame to the second frame during the bending procedure as a result of the relative vertical movement of the first and second frame and of the raising of the mobile part of the second frame, the contact area of the first frame with the glass sheet located in a vertical line with the articulation being above the articulation at the instant the latter is closed.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.14/382,974, filed Sep. 4, 2014, which is the U.S. National Stage ofPCT/FR2013/050417, filed Feb. 28, 2013, which in turn claims priority toFrench Patent Application No. 1252038, filed Mar. 6, 2012. The contentsof all of these applications are incorporated herein by reference intheir entirety.

The invention relates to a bending device comprising at least twobending frames, in particular of skeleton type, that support a glasssheet successively and at least one of which is articulated. The bentglass sheet may be intended for equipping a vehicle, in particular amotor vehicle and being incorporated, for example, into a windshield ora rear window.

Managing the formation of curvatures of glass sheets at the bendingtemperature (generally between 600° C. and 700° C.) requires the use ofmore or less complex bending supports, the geometry of which variesduring the bending. Supports are known that comprise two skeletonshaving different curvatures that pick up the glass sheet one after theother. Generally, the first skeleton has less pronounced curvatures thanthe second skeleton. The first frame may be referred to as a “sketcher”and the second frame may be referred to as a “finisher”. The sketcherhas smaller curvatures than the finisher and may even in certain casesbe flat. The glass sheet takes on its final shape on the finisherskeleton. In order to comply with the desired curvatures even more andminimize the optical defects, it is sometimes preferable for thefinisher to have articulations that are mobile during the bending.Specifically, the deformation of a glass sheet on a non-articulatedframe may result in a sliding of the edges of the sheet over the framewhich may be the cause of undulations. This sliding phenomenon isreferred to as “sliding”. Equipping a frame with one or morearticulations makes it possible to reduce the defects generated by thisphenomenon.

The present invention relates to a device for the gravity bending ofglass sheets comprising a sketcher frame that is generally notarticulated and an articulated finisher frame. Thus, the glass sheet issuccessively borne by the sketcher then by the finisher witharticulations open then by the finisher with articulations closed. Ithas now been observed that an undesirable mark could be produced on theglass at the location of the articulations when the latter are open andin contact with the glass. To resolve this problem, it has been foundthat it was advisable, in an intermediate bending phase, to support theglass sheet both by the articulated lateral lo parts of the non-closedfinisher and by the longitudinal parts of the sketcher while thefinisher is not closed. Within the context of the present application,this phase is referred to as the “intermediate phase”. When the finisheris closed, the sketcher is projected downwards with respect to thefinisher and the glass sheet is then entirely borne by the finisher inthe closed state. This is a relative movement of the two frames withrespect to one another and it would also be possible to have thefinisher moving upwards. By proceeding in this way, the glass is neverin contact with the zone of the articulations of the finisher in theopen state. The adjective “closed” used at the location of the finishermeans that its articulations are completely raised and in the finalposition (in order to give the glass sheet its final form). Theadjective “open” used at the location of the finisher means that itsarticulated part or parts are not completely raised and are not in thefinal position. The use of the terms “lateral” and “longitudinal” doesnot predict anything with respect to the relative dimensions of theparts thus designated.

Thus, the invention relates to a process for the gravity bending of aglass sheet on a support comprising a chassis, a first frame and asecond frame, the second frame being of articulated type and comprisinga mobile lateral part that passes from an open position to a closedposition by means of an articulation in the course of the bendingprocedure, the bending of the sheet beginning on the first frame whilethe second frame is in the open position, and finishing on the secondframe in the closed position, the sheet passing from the first frame tothe second frame during the bending procedure as a result of therelative vertical movement of the first and second frame and of theraising of the mobile part of the second frame, the contact area of thefirst frame with the glass sheet located in a vertical line with thearticulation being above the articulation at the instant the latter isclosed. This means that the intersection, on the one hand, of thevertical line passing through the articulation of the second frame with,on the other hand, the contact area of the first frame with the glasssheet is above the articulation at the instant the articulation isclosed.

The invention relates not only to the bending of an individual glasssheet, which may subsequently be tempered and intended, for example, tobe used as a rear window of a motor vehicle, but also the bending of atleast two glass sheets (generally two glass sheets in total) that haveto subsequently be assembled with an intermediate sheet of a polymersuch as polyvinyl butyral (PVB) in order to produce laminated glazing,in particular a windshield of a motor vehicle. For the latter type ofglazing, it is preferred to carry out the bending of the sheets intendedfor the same glazing by superposing them since thus they are bentsimultaneously and they are thus given exactly the same shape. For thebending, an interlayer powder of silica or of kieselguhr is generally,and in a known manner, introduced between the two sheets in order toprevent them from sticking. This powder is discharged after the coolingand it is then possible to carry out the assembly thereof with theinterlayer sheet of polymer material, generally made of PVB.

In particular, the bending on the support begins when the contact areaof the first frame with the sheet is entirely above the second frame.Generally, at one point of the bending process, the sheet is entirelysupported by the first frame without any contact with the second frame.

In particular, the bending on the support finishes when the contact areaof the first frame with the sheet is entirely below the contact area ofthe second frame with the sheet, the sheet then being entirely supportedby the second frame and having no contact with the first frame.

According to the invention, during the intermediate phase, and inparticular at the instant when the articulated frame is closed, theglass sheet is supported by the lateral edges of the mobile parts of thesecond frame and by the longitudinal edges of the first frame.

Preferably, for the relative vertical movement of the first frame and ofthe second frame and the transfer of the glass sheet from the firstframe to the second frame, the first frame passes inside the secondframe. According to this variant, the perimeter of the first frame issmaller than the perimeter of the second frame. It is also possible tomake the second (articulated) frame pass inside the first frame but thisvariant is not preferred. Indeed, by placing the first frame entirelyinside the second frame when seen from above, when the glass begins tobend under the effect of the combined action of heat and its weight, theedges of the glass sheet overflowing outside of the first frame stickout upwards so that these edges in fact move away from the second frameand do not risk touching it. The part of the sheet inside the firstframe can be bent without risking touching the second frame since thelatter is on the outside of the first frame. Conversely, if the secondframe were placed inside the first frame when seen from above, thenthere would be a risk that the glass supported by the first frame at thebeginning of the bending would prematurely touch the second frame,unless a very large difference in levels between the two frames wasprovided. An increase in the difference in levels between the two framesrepresents an increase in the height of the entire bending support whichmay pose a problem if the furnace inside which it must move is not highenough.

In particular, the articulated frame may comprise a single articulation,which is generally found in the central zone of each of the longitudinaledges of the second frame. Such a frame is then referred to as having“central articulation”. Such a frame then consists of two mobile partseach bearing a lateral edge of the frame.

The articulated frame may also comprise two articulations. It thencomprises two mobile parts located on either side of a fixed part. Thearticulated frame then comprises two longitudinal edges, eachlongitudinal edge being in three parts, including a central part placedbetween two parts each located on a mobile part.

In particular, for the relative vertical movement of the first frame andof the second frame and the transfer of the glass sheet from the firstframe to the second frame, the first frame may descend.

For the relative vertical movement of the first frame and of the secondframe, the following three possibilities exist:

-   -   descent of the first frame, the second frame being fixed;    -   ascent of the second frame, the first frame being fixed;    -   descent of the first frame and ascent of the second frame.

When it is said here that a frame is fixed, this is a fixity in avertical direction, it being understood that the whole of the supportaccording to the o invention may be made to move horizontally in afurnace. Indeed, the support according to the invention may be mountedon a carriage and be part of a train of identical support carriagespassing the glass sheets one after another through a furnace. Themovement of the various mobile parts of one of the supports of saidtrain (relative vertical movement of the frames of the support+closureof the articulated finisher frame) may be activated and carried outwhile the carriage moves horizontally in the furnace or else at aprecise location in the furnace after stopping the carriage.

For the relative vertical movement of the first frame and of the secondframe and the transfer of the glass sheet from the first frame to thesecond frame, it is possible to make provision to pivot the mobile partabout a pivot axis fixed to the chassis, said chassis being verticallyimmobile. The axis itself has a horizontal direction. This pivot axisdoes not correspond to the axis of a mobile articulation but is found inthe length of the longitudinal part of a mobile part. This method ofoperation is particularly suitable for a frame with a centralarticulation. The fixity of the chassis is essentially vertical since itcan be mounted on a carriage and be part of a train of identicalcarriages horizontally passing glass sheets one after another through afurnace.

The articulation of a mobile part comprises a horizontal axis. This axismay in particular be fixed horizontally but mobile vertically and ableto be moved in an oblong hole made in a guide firmly attached to thefirst sketcher frame. The guide is fixed with respect to the sketcher.In particular, the support according to the invention may comprise aguide firmly attached to the first frame, said guide being equipped withan oblong orifice, the length of which is vertical, the axis of thearticulation being engaged in said orifice and being able to movetherein vertically, and for the relative vertical movement of the firstframe and of the second frame and the transfer of the glass sheet fromthe first frame to the second frame, the first frame and also thearticulation descend so that the mobile part pivots about the pivot axisfixed to the chassis, the axis of the articulation being at the bottomof the oblong hole, then, when the articulation is closed, the firstframe continues to descend until the axis of the articulation is foundat the top of the oblong hole.

The frames in question in the present application have a flat uppersurface intended to support the glass sheet. Generally, this uppersurface has a width of between 1 and 100 mm. The frames may especiallybe of skeleton type. A skeleton is a thin strip of metal having one ofits edges upwards in order to support the glass, the thickness of saidedge generally ranging from 1 to 5 mm and more generally from 2 to 3.5mm. At the end of the bending, the finisher frame is in continuouscontact, via its flat upper surface, with the glass. The bending frames,in particular of skeleton type, are preferably coated with a fibrousmaterial of the type of a felt or canvass of metallic and/or ceramicrefractory fibers, as is well known to a person skilled in the art. Thismaterial is generally referred to as an “interlayer”. These felts reducethe marking of the glass. This interlayer fibrous material generally hasa thickness ranging from 0.3 to 1 mm. For simplification, it isconsidered that the interlayer is part of the frame within the meaningof the invention, the term frame also taking on a quite general meaninginsofar as it is a support of annular type for the periphery of theglass sheet. Thus, a “contact area of a frame” with the glass sheet isthe area of the interlayer if the frame is coated thereby. The twoframes in relative vertical movement with respect to one another aresufficiently far apart from one another so as not to rub during saidmovement. Thus, if they must be equipped with an interlayer, a distanceof at least 3 mm and even at least 4 mm is generally provided betweenthe two frames before assembly of the interlayer.

Preferably, the movements of the various parts of the support accordingto the invention are carried out in a controlled manner, that is to sayat a controlled speed, owing to which the glass sheets are very stableon the successive frames and, for example, do not jump around during theactivation of a mechanism. Thus, it is possible in particular to use themechanism described in WO 2007/077371 and in particular its FIGS. 3 and4 in order to make the sketcher frame descend with respect to thefinisher frame. It is therefore sufficient subsequently to connect themechanism for raising the mobile parts of the finisher to the drop ofthe sketcher so that all of the movements of the various parts of thesupport according to the invention (relative vertical movement of thetwo frames+raising of the mobile parts of the finisher) are controlled.FIG. 5 of the present application shows how it is possible to connectthe mechanism for o raising the mobile parts of the finisher to the dropof the sketcher.

The movement of the various mobile elements of the support represent achange in shape of the contact area of the support with respect to thesupported glass. This change in shape may be controlled by a controlsystem comprising a movement generator system and a transmission member(which can pass through a wall of the furnace) in order to transmit saidmovement to the support and control the change in shape. The rate ofchange in shape is regulated by regulating the speed of the movementgenerated by the movement generator system, which may be placed outsidethe furnace. Placing the movement generator system outside the furnaceis advantageous if it comprises electromechanical members unable towithstand the bending temperatures. This movement is transmitted to thesupport by a transmission member. If the movement generator system isplaced outside the furnace, the transmission member passes through atleast one of the walls of the furnace (encompassing the side walls butalso the floor and the roof). The figures described below illustrate theinvention applied to simple shapes of glass sheets (rectangular sheetswith relatively constant radii of curvature), but it is clearlyunderstood that the invention can be applied to much more complex shapesboth as regards the contour of the glass sheets and their radii ofcurvature.

The invention also relates to the bending support described previouslyfor implementation of the bending process. Thus, the invention alsorelates to a support for the gravity bending of a glass sheet,comprising a first frame and a second frame, the second frame being ofthe articulated type and comprising a mobile lateral part that can passfrom an open position to a closed position by means of an articulation,the first frame and the second frame being mobile with respect to oneanother via a relative vertical movement, the relative vertical movementof the frames being connected to the closing or opening movement of thearticulation, the contact area of the first frame with the glass sheetand located in a vertical line with the articulation being above thearticulation at the moment the latter is closed.

The lowering of the first frame (sketcher) with respect to the secondframe is accompanied by the closure of the articulation. At the momentwhen the articulation closes, the contact area of the first frame withthe glass sheet and which is located in a vertical line with thearticulation is above the articulation. Next, the first frame maycontinue its descent relative to the second frame and leave the glasssheet resting entirely on the second frame, with the articulationclosed.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a support comprising two frames, a virtually flat sketcherand a finisher with a central articulation according to an embodiment ofthe invention;

FIG. 2 shows a support comprising two frames, a virtually flat sketcherand a finisher with two articulations according to an embodiment of theinvention;

FIG. 3 shows the relative positions of two frames of skeleton type andof the articulated parts at various stages of the gravity bendingaccording to an embodiment of the invention;

FIG. 4 shows the relative positions of two frames of skeleton type andof the articulated parts at various stages of the gravity bendingaccording to an embodiment of the invention, and

FIG. 5 shows the relative positions of two frames of skeleton type andof the articulated parts at various stages of the gravity bendingaccording to an embodiment of the invention.

FIGS. 1 and 2 show the type of double bending frames (here of skeletontype) to which the invention refers. FIG. 1 shows a support comprisingtwo frames, a virtually flat sketcher 100 and an articulated finisher101 with central articulation 102. The finisher comprises two mobileparts 103 and 104 that can pivot about an articulation 102 (reference ismade to “an articulation” but of course it is a pair of articulations,one per longitudinal edge).

The sketcher comprises two lateral edges 105 and 106 and twolongitudinal edges 107 and 108. The mobile parts of the finisher eachcomprise a lateral edge 109 and 110 of the finisher. The finisher alsocomprises two longitudinal edges, each longitudinal edge being dividedinto two parts within each mobile part. In a), the glass sheet issupported only by the sketcher 100, the finisher being open (mobileparts 103 and 104 not raised) and entirely below the level of thecontact area of the sketcher with the glass sheet. The glass sheetbegins its bending on the sketcher. Seen from above, the sketcher liesentirely inside of the finisher. During the bending, the sketcherdescends and passes entirely inside of the finisher which closes. Theglass sheet then passes from the sketcher to the finisher. In b), at theend of the bending, the finisher 101 is closed (mobile parts 103 and 104raised) and its contact area with the glass is entirely above thecontact area of the glass with the sketcher. Thus, the glass no longerhas contact with the sketcher 100.

FIG. 2 represents a support comprising two frames, a virtually flatsketcher 200 and a finisher 201 having two articulations 202 and 203(these are of course two pairs of articulations, each longitudinal edgecomprising two articulations per longitudinal edge). The longitudinaledges of the finisher comprise central parts between the two mobileparts. In a), the glass sheet is supported solely by the sketcher 200,the finisher being open (mobile parts 204 and 205 not raised) andentirely below the level of the contact area of the sketcher with theglass sheet. The glass sheet begins its bending on the sketcher. Seenfrom above, the sketcher lies entirely within the finisher. During thebending, the sketcher descends and passes entirely within the finisher,which closes. The glass sheet then passes from the sketcher to thefinisher. In b), at the end of the bending, the finisher 201 is closed(mobile parts 204 and 205 raised) and its contact area with the glass isentirely above the contact area of the glass with the sketcher. Thus,the glass no longer has contact with the sketcher 200.

FIG. 3 represents a bending support comprising two frames of skeletontype, a flat sketcher 1 and a articulated finisher 2 having centralarticulation comprising two articulated mobile parts 3 and 4. Therelative positions of the two skeletons and also that of the articulatedparts are seen at various stages of the gravity bending from a) to d).The two skeletons are of annular type and support the periphery of atleast one glass sheet. The sketcher lies within the finisher, seen fromabove. In a), the glass sheet (not represented) rests solely on thesketcher 1. During the bending on the sketcher, the glass sheet does notrisk touching the finisher 2. Indeed, it sinks in its internal zone sothat its edges rise and even move away from the finisher. In b), thefinisher is in the process of closing and its two articulated parts 3and 4 are slightly raised. At this intermediate stage, the sheet restsboth on the ends 5 and 6 of the finisher, which includes the lateraledges of the finisher, and on the central zones 7 of the longitudinaledges of the sketcher. The glass is therefore protected from any contactwith the articulation in a vertical line 9 therewith, In c), thearticulation 8 of the finisher 2 has just closed completely and thesketcher is still seen just above the articulation of the finisher. Theglass sheet is therefore, at this stage, mainly supported by thefinisher and also slightly by the sketcher in its central zones 7 of thelongitudinal edges and in any case in a vertical line with thearticulation. In d), the finisher is in the same state as in c), that isto say completely closed, but the sketcher 1 is retracted downwards, sothat the glass sheet is entirely supported by the finisher 2. Theprocedure from a) to d) shows how it is possible for the glass sheetnever to come into contact with the articulation 8 of the finisher ifthe latter is not completely closed. From a) to d) there was acontinuous relative vertical movement of the sketcher and of thefinisher making the sketcher pass through the finisher, accompanied bythe closure of the finisher.

FIG. 4 represents a bending support comprising two skeletons, a flatsketcher 10 and an articulated finisher 11 comprising two mobile lateralparts 12 and 13 on either side of central parts 14 of longitudinal edgesof the finisher. The relative positions of the two skeletons and alsothat of the articulated parts are seen at various stages of the gravitybending from a) to d). The two skeletons are of annular type and supportthe periphery of at least one glass sheet. The sketcher is inside thefinisher, seen from above, In a), the glass sheet rests solely on thesketcher 10. During the bending on the sketcher, the glass sheet doesnot risk touching the finisher 11. Indeed, it sinks in its internal zoneso that its edges rise and where appropriate even move away from thefinisher. In b), the finisher is in the process of closing and its twomobile parts 12 and 13 are slightly raised. At this intermediate stage,the sheet rests both on the ends 15 and 16 of the mobile parts of thefinisher, which includes the lateral edges of the finisher, and on thecentral zones 17 of the longitudinal edges of the sketcher 10.

The glass is therefore protected from any contact with the articulationsin vertical lines 20 and 21 therewith. In c), the articulations 18 and19 of the finisher 11 have just closed completely and the sketcher isstill seen just above said articulations of the finisher. The glasssheet is therefore, at this stage, supported both by the finisher 11 andalso by the sketcher in its central zones 17 of the longitudinal edges.In d), the finisher 11 is in the same state as in c), that is to saywith articulations completely closed, but the sketcher 10 is retracteddownwards and is below the articulations 18 and 19 so that the glasssheet is entirely supported by the finisher 11. The procedure from a) tod) shows how it is possible for the glass sheet never to come intocontact with the articulations 18 and 19 of the finisher if the latteris not completely closed. From a) to d) there was a continuous relativevertical movement of the sketcher and of the finisher making thesketcher pass through the finisher, accompanied by the closure of thefinisher.

FIG. 5 represents a bending support comprising two frames of skeletontype, a flat sketcher 31 and an articulated finisher 32 having centralarticulation comprising two articulated mobile parts 33 and 34. Therelative positions of the two skeletons and also that of the articulatedparts are seen at various stages of the gravity bending from a) to c).Each mobile part comprises, in its length, a pivot axis 35 and 36, theposition of which is fixed with respect to the chassis 37 of the device(the vertical fixity of the chassis is symbolized by the representationof the “ground”). These two pivot axes 35 and 36 do not therefore movein terms of height. The mobile parts 33 and 34 may move slightly withrespect to these pivot axes 35 and 36 owing to the oblong holes 50 and51 made in these mobile parts about these pivot axes. The two mobileparts 33 and 34 are furthermore connected together by another pivot axis38 in a central position. This pivot axis 38 can be moved vertically ina guide 39 comprising an oblong orifice 40, the length of which isvertical. The axis 38 may move vertically inside the oblong hole 40. Thesketcher 31 and the guide 39 are firmly attached together in a fixedmanner owing to the connecting elements 52 and 53. From a) to c), theprinciple of replacing the sketcher by the finisher is that alreadyexplained by FIG. 3. In a), only the sketcher bears the glass sheet (notrepresented) and a first bending takes place thereon. Next, the sketcherbegins to descend, which enables the axis 38 to also descend under theeffect of the weight of the mobile parts close to the axis 38. Thislowering of the axis 38 makes the ends of the mobile parts rise bypivoting about the pivot axes 35 and 36. The ends of the mobile partsthen come above the sketcher and partially take charge of the glasssheet. At this stage (stage b) of FIG. 5), the glass sheet rests on theends 41 and 42 of the mobile parts, which includes the lateral edges ofthe mobile parts, and on the central zone 43 of the longitudinal partsof the sketcher. The finisher is closed, the ends of its mobile partsbeing completely raised. Stops (not represented) firmly attached to thechassis mark the end of the raising of the ends of the mobile parts,that is to say also the end of the descent of the zones 44 and 45 of themobile parts located between the central pivot axis 38 and the pivotaxes 35 and 36. At this stage, the sketcher remains above the closedcentral articulation 38, therefore protecting the glass in the verticalline 46 with the articulation. The sketcher may continue to descendcarrying along the guide 39. The pivot axis 38 of the articulationremains fixed with respect to the chassis. It is the guide 39 whichcontinues to descend, so that the central pivot axis 38 is found at thetop of the oblong hole at the end of the procedure represented in c).The finisher 32 is then completely above the sketcher 31.

1. A support for the gravity bending of a glass sheet, comprising afirst frame and a second frame, the second frame being articulated andcomprising a mobile lateral part that can pass from an open position toa closed position by means of an articulation, the first frame and thesecond frame being mobile with respect to one another via a relativevertical movement, the relative vertical movement of the first andsecond frames being connected to the closing or opening movement of thearticulation, a contact area of the first frame with the glass sheet andlocated in a vertical line with the articulation being above thearticulation at the moment the articulation is closed.
 2. The support asclaimed in claim 1, wherein at the instant when the articulated secondframe is closed, the glass sheet is supported by lateral edges of mobileparts of the articulated second frame and by longitudinal edges of thefirst frame.
 3. The support as claimed in claim 1, wherein for therelative vertical movement of the first frame and of the second frame,one of the first and second frames passes inside the other one of thefirst and second frames.
 4. The support as claimed in claim 1, whereinfor the relative vertical movement of the first frame and of the secondframe and a transfer of the glass sheet from the first frame to thesecond frame, the mobile part pivots about a pivot axis fixed to achassis of the support, said chassis being vertically immobile.
 5. Thesupport as claimed in claim 4, wherein the support comprises a guidefirmly attached to the first frame, said guide being equipped with anoblong orifice, a length of which is vertical, an axis of thearticulation being engaged in said orifice and being able to movetherein vertically, and wherein for the relative vertical movement ofthe first frame and of the second frame and a transfer of the glasssheet from the first frame to the second frame, the first frame and thearticulation descend so that the mobile part pivots about the pivot axisfixed to the chassis, the axis of the articulation being at a bottom ofthe oblong hole, then, when the articulation is closed, the first framecontinues to descend until the axis of the articulation is found at atop of the oblong hole.
 6. The support as claimed in claim 1, whereinthe articulated second frame comprises a central articulation or twoarticulations in each of its longitudinal edges.
 7. The support asclaimed in claim 1, wherein the first frame is a non-articulated frame.8. A support for the gravity bending of a glass sheet, the supportcomprising: a non-articulated frame; an articulated frame, each of thenon-articulated frame and the articulated frame being configured tosupport the glass sheet, the articulated frame comprising a mobilelateral part that is movable between an open position and a closedposition with an articulation, the non-articulated frame and thearticulated frame being movable with respect to one another via arelative vertical movement, and a guide configured to guide the relativevertical movement of the non-articulated frame and the articulated framein a manner that the relative vertical movement of the non-articulatedframe and the articulated frame creates a closing or opening movement ofthe articulation, wherein the guide is configured to guide the relativevertical movement so that a contact area of the non-articulated framewith the glass sheet and located in a vertical line with thearticulation is above the articulation at the moment the articulation isclosed.
 9. The support as claimed in claim 8, wherein thenon-articulated frame is fixed to the guide so that the non-articulatedframe and the guide are movable in unison.
 10. The support as claimed inclaim 8, wherein the guide is movable and limits movement of the mobilepart between the closed and open position.
 11. The support as claimed inclaim 8, wherein at the instant when the articulated frame is closed,the glass sheet is supported by lateral edges of mobile parts of thearticulated frame and by longitudinal edges of the non-articulatedframe.
 12. The support as claimed in claim 8, wherein for the relativevertical movement of the non-articulated frame and of the articulatedframe, one of the non-articulated frame and articulated frame passesinside the other one of the non-articulated frame and articulated frame.13. The support as claimed in claim 8, wherein for the relative verticalmovement of the non-articulated frame and of the articulated frame and atransfer of the glass sheet from the non-articulated frame to thearticulated frame, the mobile part pivots about a pivot axis fixed to achassis of the support, said chassis being vertically immobile.
 14. Thesupport as claimed in claim 13, wherein the guide is equipped with anoblong orifice, a length of which is vertical, an axis of thearticulation being engaged in said orifice and being able to movetherein vertically, and wherein for the relative vertical movement ofthe non-articulated frame and of the articulated frame and a transfer ofthe glass sheet from the non-articulated frame to the articulated frame,the non-articulated frame and the articulation descend so that themobile part pivots about the pivot axis fixed to the chassis, the axisof the articulation being at a bottom of the oblong hole, then, when thearticulation is closed, the non-articulated frame continues to descenduntil the axis of the articulation is positioned at a top of the oblonghole.
 15. The support as claimed in claim 8, wherein the articulatedframe comprises a central articulation or two articulations in each ofits longitudinal edges.